Tissue planing assemblies and methods

ABSTRACT

In one embodiment, a tissue planing assembly includes a base frame, a plurality of disassemblable components assembled to the base frame and having a ready configuration, a sample conveyor, a blade assembly configured to be coupled to the base frame, a control unit communicatively coupled to the sample conveyor, and one or more component sensors communicatively coupled to the control unit. The plurality of disassemblable components is configured to support a tissue sample. The sample conveyor is configured to convey the tissue sample through the blade assembly. The one or more components sensors are configured to output a signal indicative of at least one of the plurality of disassemblable components missing from the ready configuration, wherein the control unit prohibits operation of the sample conveyor when at least one of the plurality of disassemblable components is missing from the ready configuration.

TECHNICAL FIELD

The present specification generally relates to tissue planing assembliesand methods and, more specifically, tissue planing assemblies andmethods for processing a tissue sample.

BACKGROUND

Skin allografts manufactured from human donor tissue are used forvarious medical applications. Most notably, allograft skin is used forthe purpose of protecting wounds and providing a scaffold for thepurpose of promoting new skin cell development and natural healing.Allograft skin consists of both the epidermis and a portion of thedermis of the donor. This is also known as split-thickness (S/T) skin.S/T skin is generally about 0.3 to about 0.65 mm thick and is somewhatdifficult to obtain in sections with a surface area larger than 4 in. by6 in. due to limitations in existing skin recovery methods.

One common method for recovering S/T skin is to use a dermatome orsimilar bladed instrument to remove the desired thickness directly fromthe donor. Another method which is commonly used is to remove sectionsof full-thickness (F/T) skin from the donor to recover S/T skintherefrom. F/T skin consists of the epidermis, dermis and a portion ofsubcutaneous fat layer and potentially muscle under the dermis. Theadvantage of recovering F/T skin over the direct recovery method is thatthe larger sections of skin can then be laid flat and processed torecover the needed S/T skin without the impediment of the donor'sanatomical curves and body form. In both cases S/T skin is recovered byprocessing the tissue epidermis side up.

However, current methods are limited to producing S/T skin graftproducts with nominal widths of four inches or less based on the widthof the blade used to recover the graft. The narrow strips may not be aseffective in wound treatment as strips of greater size. Accordingly, aneed exists for tissue planing assemblies and methods to produce skinallograft products of greater size than traditional methods.

SUMMARY

In one embodiment, a tissue planing assembly includes a base frame, aplurality of disassemblable components assembled to the base frame andhaving a ready configuration, a sample conveyor, a blade assemblyconfigured to be coupled to the base frame, a control unitcommunicatively coupled to the sample conveyor, and one or morecomponent sensors communicatively coupled to the control unit. Theplurality of disassemblable components is configured to support a tissuesample. The sample conveyor is configured to convey the tissue samplethrough the blade assembly. The one or more components sensors areconfigured to output a signal indicative of at least one of theplurality of disassemblable components missing from the readyconfiguration, wherein the control unit prohibits operation of thesample conveyor when at least one disassemble component of the pluralityof disassemblable components is missing from the ready configuration.

In another embodiment, a tissue planing assembly includes a base frame,a sample conveyor coupled to the base frame, a blade assembly coupled tothe base frame, a control unit communicatively coupled to the sampleconveyor; and a first hand control and a second hand controlcommunicatively coupled to the control unit. The sample conveyor isconfigured to convey a tissue sample through the blade assembly. Thecontrol unit executes logic to operate the sample conveyer only whenboth the first hand control and the second hand control are activated.

In yet another embodiment, a method of processing a tissue sample with atissue planing assembly includes placing a tissue sample epidermis sidedown on a front tray of the tissue planing assembly, wherein a portionof the tissue sample is contacted to a sample conveyor. The methodfurther includes determining with one or more component sensors whetherone or more disassemblable components are assembled to a base frame ofthe tissue planing assembly in a ready configuration, outputting a readysignal when it is determined that the one or more disassemblablecomponents of the tissue planing assembly are assembled to the baseframe of the tissue planing assembly in the ready configuration, andconveying the tissue sample with the sample conveyor through a bladeassembly of the tissue planing assembly. The tissue sample is onlyconveyed when the one or more disassemblable components of the tissueplaning assembly are assembled to the base frame in the readyconfiguration.

In yet another embodiment, a tissue planing assembly includes a baseframe, a sample conveyor coupled to the base frame, and a blade assemblycoupled to the base frame. The sample conveyor is configured to conveythe tissue sample through the blade assembly. The blade assemblyincludes a shoe defining a groove, a blade positioned on a top surfaceof the shoe proximate to the groove, a blade clamp configured to rigidlyclamp the blade to the shoe, and one or more spacers positionable withinthe groove adjacent to the blade to adjust a cutting depth of the blade.

These and additional features provided by the embodiments describedherein will be more fully understood in view of the following detaileddescription, in conjunction with the drawings.

BRIEF DESCRIPTION OF THE DRAWINGS

The embodiments set forth in the drawings are illustrative and exemplaryin nature and not intended to limit the subject matter defined by theclaims. The following detailed description of the illustrativeembodiments can be understood when read in conjunction with thefollowing drawings, where like structure is indicated with likereference numerals and in which:

FIG. 1 depicts a tissue sample, according to one or more embodimentsshown and described herein;

FIG. 2A depicts a front perspective view of a tissue planing assembly,according to one or more embodiments shown and described herein;

FIG. 2B depicts a rear perspective view of the tissue planing assemblyof FIG. 2A, according to one or more embodiments shown and describedherein;

FIG. 3A illustrates a cross section of the tissue planing assembly ofFIG. 2A transverse to a sample conveyor having a first blade position,according to one or more embodiments shown and described herein;

FIG. 3B illustrates the cross section of the tissue planing assembly ofFIG. 3A with a second blade position, according to one or moreembodiments shown and described herein;

FIG. 4A illustrates a perspective view of a shoe of the tissue planingassembly of FIG. 2A, according to one or more embodiments shown anddescribed herein;

FIG. 4B illustrates a perspective view of the shoe of FIG. 4A with aspacer positioned within a groove of the shoe, according to one or moreembodiments shown and described herein;

FIG. 4C illustrates the shoe of FIG. 4B with a cutting blade positionedon a top surface of the shoe, according to one or more embodiments shownand described herein;

FIG. 5 depicts a connection between a front tray and a base frame of thetissue planing assembly of FIG. 2A, according to one or more embodimentsshown and described herein;

FIG. 6A illustrates a perspective view of a rear tray mounted on to thebase frame of the tissue planing assembly of FIG. 2B, according to oneor more embodiments shown and described herein;

FIG. 6B illustrates a side view of an alternative orientation of therear tray mounted on to the base frame of the issue planing assembly,according to one or more embodiments shown and described herein;

FIG. 7 illustrates a perspective view of the catch tray mounted onto thebase frame 102 of the tissue planing assembly of FIG. 2B, according toone or more embodiments shown and described herein;

FIG. 8 depicts a perspective view of the hold down roller connected to abase frame of the tissue planing assembly of FIG. 2A, according to oneor more embodiments shown and described herein;

FIG. 9 depicts a schematic diagram of the tissue planing assembly ofFIG. 2A, according to one or more embodiments shown and describedherein;

FIG. 10 illustrates a flow diagram representing an exemplary method ofprocessing a tissue sample with the tissue planing assembly of FIG. 2A,according to one or more embodiments shown and described herein;

FIG. 11A illustrates a tissue sample prepared for processing, accordingto one or more embodiments shown and described herein; and

FIG. 11B illustrates the tissue sample of FIG. 11B being processed,according to one or more embodiments shown and described herein.

DETAILED DESCRIPTION

Reference will now be made in detail to various embodiments of a tissueplaning assembly. In general, tissue planing assemblies as providedherein include a sample conveyor, a control unit communicatively coupledto the sample conveyor and operable to operate the sample conveyor toconvey a tissue sample toward a blade assembly such that a tissueplaning operation may be performed on the tissue sample. In someembodiments, the tissue planing assembly further includes a plurality ofdisassemblable components that are assembled to a base frame of thetissue planing assembly in a ready configuration wherein the tissueplaning assembly is ready to perform the tissue planing operation. Oneor more component sensors may be provided that output a signal to thecontrol unit indicative of whether or not one of the one or moredisassemblable components are missing from the ready configuration. If acomponent is missing, the control unit can prohibit operation of thesample conveyor and prevent the planing operation. Such embodiments mayaid operators in determining that the tissue planing assembly is ready(i.e., properly assembled) to perform a planing operation. Variousembodiments of the tissue planing assembly 100 will be described in moredetail herein.

Referring to FIG. 1, a tissue sample 10 is generally illustrated. Thetissue sample 10 is a full thickness (F/T) human skin sample. It isnoted that while the present disclosure is directed to planing humanskin samples, the embodiments described herein can also apply tonon-human tissue samples (e.g., bovine, ovine, suidae, etc.) F/T skinsamples generally includes an epidermis layer 12 and a dermis layer 14.Attached to the dermis layer 14 opposite the epidermis layer 12 may bean adipose layer 16 including subcutaneous fat and possibly some muscletissue. It is noted that where a tissue sample is described as having anepidermis layer 12 and dermis layer 14, the presence of an adipose layer16 is not precluded.

F/T skin samples are typically removed from a donor's back, upper andlower extremities, and occasionally abdomen in large sections via sharpdissection with a scalpel and/or other tissue cutting devices. Theadvantage of recovering F/T skin is that large sections of skin can beremoved from the donor, laid flat, and processed without the impedimentof the donor's anatomical curves and body form. Using the methodologiesprovided herein, large F/T skin samples may translate into larger piecesof split thickness (S/T) skin samples with a more consistent thicknessthan presently available using traditional S/T skin recoveringtechniques.

S/T skin includes the epidermis layer 12 and a portion of the dermislayer 14. S/T skin can be used as skin grafts to better aid healing inpatients. S/T skin is generally between about 0.3 and about 0.65 mmthick (e.g., 0.45 mm thick). One drawback of beginning with F/T skin isthat it may be difficult to hold the tissue sample 10 firmly in placethroughout a tissue planing operation to recover the S/T skin. Undertraditional processing techniques, a technician may need to hold the F/Tskin sample with their hands while simultaneously using a cutting deviceto obtain the S/T skin.

As noted above, under traditional S/T skin recovering techniques,cutting devices (e.g. dermatomes, amalgatomes, and the like) are used todirectly remove the desired S/T skin from the F/T skin sample. That is,the F/T skin sample is processed epidermis side up and a cutting deviceis applied directly to the epidermis from above by an operator to removethe S/T skin. Conventional S/T skin grafts recovering techniquestherefore limit the resulting S/T graft size to the cutting width of thecutting device, which is generally about 6 inches wide or less. Thesecutting devices are applied manually by an operator and, therefore, needto be sized so as to be controllable and easy to control within the handof an operator. However, wider S/T skin grafts are desirable to bettermeet demands of patients with larger wounds. As will be described ingreater detail herein, using the tissue planing assemblies and methodsdescribed herein allow for processing the tissue sample 10 epidermisside down with a much wider blade assembly resulting in larger width S/Tskin grafts.

Referring to FIGS. 2A and 2B, a front perspective view and a rearperspective view of the tissue planing assembly 100 is respectivelyillustrated. The tissue planing assembly 100 includes a base frame 102,a sample conveyor 120, a blade assembly 130, a plurality of removabletrays including a front tray 108, a rear tray 110, and a catch tray 112,and a rotatable hold down roller 172. The tissue planing assembly 100may further include one or more component sensors 170, a control unit150, a control unit housing 151, a status indicator 155, a user inputmodule 158, and an emergency stop 180. While these various componentsare illustrated as part of a single tissue planing assembly, tissueplaning assemblies having a greater or fewer number of components arepossible and contemplated.

The base frame 102 supports the various components of the tissue planingassembly 100 relative to one another such that a tissue planingoperation may be performed. It is noted that the base frame 102 may bemade from any material that can be repetitively washed and disinfected(e.g., stainless steel). In some embodiments, the base frame 102 may beelectro-polished or provided with a similar high durability and mirroredsurface treatment such that the base frame 102 may be easily cleaned andsterilized.

Still referring to FIGS. 2A and 2B, mounted to the base frame 102 is asample conveyor 120. The sample conveyor 120 may be any deviceconfigured to pull a tissue sample from a sample support surface 121 ofthe front tray 108 and through the blade assembly 130 such that a tissueplaning operation can be performed on a tissue sample. FIGS. 3A and 3Billustrate a cross section of the tissue planing assembly 100 transverseto the sample conveyor 120. In the illustrated embodiment, the sampleconveyor 120 includes a gripping roller 140 having a plurality of teeth141 extending from a peripheral surface of the gripping roller 140. Theplurality of teeth 141 of the gripping roller 140 allows the sampleconveyor 120 to interact with a tissue sample so as to be able to propelthe tissue sample toward the blade assembly 130 (see also FIG. 11B). Thesample conveyor 120 may include a motor, not shown, to rotatively drivethe gripping roller 140. In some embodiments, and as will be describedin greater detail herein, the control unit 150 can be communicativelycoupled to the sample conveyor 120, and execute logic to selectivelyoperate or disable operation of the sample conveyor 120.

As best seen in FIGS. 2A-3B, the blade assembly 130 is positionedclosely adjacent to the gripping roller 140 of the sample conveyor 120so as to be able to plane a tissue sample as a tissue sample is directedinto the blade assembly 130 by the gripping roller 140 (see also FIG.11B). The blade assembly 130 includes an elongated cutting blade 132mounted on a shoe 134 by a blade clamp 136. The blade 132 further has acutting edge 133 that extends beyond the shoe 134 and the blade clamp136 so as to be exposed and capable of performing a tissue planingoperation.

Referring specifically to FIG. 3A, the shoe 134 has a top surface 135and a groove 142 formed within the top surface 135 of the shoe 134. Thecutting blade 132 may sit on the top surface 135 of the shoe such thatthe cutting edge 133 extends beyond the shoe 134. A portion of thecutting blade 132 may extend over the groove 142. Positioned within ofthe groove 142, in the longitudinal (+Y) direction may be an aperture144 for receiving a fastener 137 from the blade clamp 136. The aperture144 may extend through a bottom surface 146 of the shoe 134 to providefor drainage of fluids (e.g., saline) used to aid in the performance ofa tissue planing operation on a tissue sample.

The blade clamp 136 includes a substantially planar clamping surface 138that is directed to the top surface 135 and groove 142 of the shoe 134.The blade clamp 136 may include a fastener 137 for releasably fasteningthe clamp and the shoe 134 together so as to clamp the cutting blade 132therebetween.

In some embodiments, the position of the blade 132 in the longitudinaldirection (+/−Y) may be adjusted such that a greater or lesser amount ofthe cutting blade 132 is exposed beyond the shoe 134 and the blade clamp136, which adjusts a cutting depth of the blade 132. In someembodiments, a spacer 188 may be positioned within the groove 142 of theshoe 134 behind the blade 132 and clamped into place by the blade clamp136 to allow the blade 132 to shift in the +Z/−Y quadrant. As notedabove, this blade translation may allow for adjustment of a thickness ofa finished skin graft while maintaining a uniform and consistent output.

FIG. 3A illustrates a first spacer 192 corresponding to a first cuttingdepth. In the illustrated embodiment the first spacer 192 includes anopening 160 formed therein to allow the fastener 137 to passtherethrough to clamp the first spacer 192 into place. In thisembodiment, the first spacer 192 is positioned such that there is a gap197 formed between the first spacer 192 and an end 143 of the groove142. The cutting blade 132 may bridge this gap 197 to contact a leadingedge 164 of the first spacer 192 such that the blade 132 is unable totravel further in the +Y direction of the depicted coordinate axes.

FIG. 3B illustrates a second spacer 194 corresponding to a secondcutting depth. In this embodiment, the second spacer 194 includes anopening 160 formed therein to allow the fastener 137 to passtherethrough to clamp the second spacer 194 into place. In this case,the second spacer 194 extends to the end 143 of the groove 142. Thecutting blade 132 is positioned so as to be in contact with the leadingedge 164 of the second spacer 194. In this case, the second spacer 194causes the cutting edge 133 of the cutting blade 132 to extend furtherin the −Y direction of the depicted coordinate axes than the position ofthe cutting edge 133 illustrated in FIG. 3A.

Referring now to FIGS. 4A-4C, FIG. 4A illustrates a perspective view ofan embodiment of the shoe 134 without a blade clamp, spacer, or blade.As shown the groove 142 extends along a length of the blade clamp in the−X direction of the depicted coordinate axes. Positioned within thegroove 142 are several apertures 144 for receiving a fastener for theblade clamp 136 (shown in FIGS. 3A and 3B). Though, three apertures 144are illustrated a greater or fewer number of apertures 144 arecontemplated and possible. In some embodiments, one or more dowel rods145 may extend from the groove 142 which may be used to position aspacer within the groove 142.

FIG. 4B illustrates a spacer 188 positioned within the groove 142. Thespacer 188 may include as many openings 160 to match the number ofapertures within the shoe 134. As shown, the one or more dowel rods 145of the shoe 134 may extend through dowel rod openings 162 formed withinthe spacer 188 to position the spacer 188 relative to the end 143 of thegroove 142. FIG. 4C illustrates the blade 132 positioned on the topsurface 135 of the shoe 134 and contacting a leading edge 164 of thespacer 188. Accordingly, the spacer 188 extends above the top surface135 of the shoe 134 to be flush with a top surface of the cutting blade132.

One or more spacers may be provided. In some embodiments, severalspacers may be provided to allow to standardized cutting depths to bechosen for a particular product. The several spacers may generally havethe same dimensions, but are positioned within the groove 142 so as toextend closer or farther from the end 143 of the groove 142.Accordingly, the positioning of the openings 160 for the fastener and/orthe dowel rod openings 162 within the spacer 188 may vary betweendifferent spacers. For example, a spacer 188 that has a leading edge 164that is to be positioned closer to the end 143 of the groove 142 (seeFIG. 3B) may have the opening 160 formed therein positioned farther backin the +Y direction of the depicted coordinate axes than that of aspacer 188 having a leading edge 164 that is to be positioned fartherfrom the end 143 of the groove 142 (see FIG. 3A).

It is noted that when assembled, the blade 132 is held rigidly in placeby the shoe 134, the clamp 136, and the spacer 188 with respect to thebase frame 102. That is, a cutting depth of the blade 132 is configuredto remain constant throughout processing such that a S/T skin grafthaving a substantially uniform thickness can be reliably and repeatedlyachieved.

In some embodiments, at least some of the various components can beeasily assembled and disassembled to and from the base frame 102.Accordingly, the various components that are easily assembled anddisassembled to and from the base frame 102 define a plurality ofdisassemblable components. Generally, the plurality of disassemblablecomponents may be assembled to or disassembled from the base frame 102without the need of separate tools. For example the plurality ofdisassemblable components may mount onto the base frame 102 using slots,pins (e.g., spring loaded pins), and the like. The plurality ofdisassemblable components may include, without limitation, one or moreof the plurality of removable trays (e.g., the front tray 108, the reartray 110 and/or the catch tray 112), and the rotatable hold down roller172. However, other components may also be included as one of theplurality of disassemblable components without departing from the scopeof the present disclosure.

The plurality of disassemblable components may be assembled to the baseframe 102 in a ready configuration, such as illustrated in FIGS. 2A and2B, wherein the plurality of disassemblable components are mounted on tothe base frame 102, such that the tissue planing assembly 100 is readyto perform a tissue planing operation. As noted above, the tissueplaning assembly 100 may include one or more component sensors 170 thatare configured to output a signal indicative of at least one of theplurality of disassemblable components missing from the readyconfiguration. As will be described in greater detail herein, when atleast one of the plurality of disassemblable components is missing fromthe ready configuration, by either being out of alignment or missingcompletely from the tissue planing assembly 100, the control unit 150can execute logic to prohibit operation of the sample conveyor 120.

Still referring to FIGS. 2A, and 2B, removably supported on the baseframe 102 is the front tray 108. In some embodiments, the front tray 108may be electro-polished or provided with a similar high durability andmirrored surface treatment such that the front tray 108 may be easilycleaned and sterilized. Alternatively, or in addition to such treatment,the front tray 108 may be made from a material capable of repeatedwashing and sterilization (e.g., stainless steel). Referring also toFIG. 11A, the front tray 108 may be used to support a tissue sample 10thereon as the tissue sample 10 is introduced to blade assembly 130 andthroughout processing. The front tray 108 includes a sample supportsurface 121 for supporting the tissue sample 10 thereon and one or moresidewalls that extend from the support surface. For example, in theillustrated embodiment, the front tray 108 includes a longitudinal sidewall 124 and two lateral side walls 122 that are perpendicular to thelongitudinal sidewall 124. The side walls may extend perpendicularlyfrom the sample support surface 121 in the vertical direction (−Z) andmay define hand holds 123 formed therein. The hand holds 123 may allow auser to manually manipulate the front tray 108 such that the front tray108 may be easily assembled and disassembled to the base frame 102. Thefront tray 108 may be light enough for a single user to manipulate. Forexample, in some embodiments the front tray weights less than 25 pounds(e.g., 23 lbs).

The front tray 108 may be mounted to the base frame 102 using any meansthat does not require tools to assemble or disassemble the front tray108 to or from the base frame 102. For example the front tray 108 may bemounted on to the base frame 102 using, pins, slots, or a combinationthereof. Accordingly, the front tray 108 may be one of thedisassemblable components of the plurality of disassemblable components.

For example, FIG. 5 illustrates a perspective view of a connectionbetween the front tray 108 and the base frame 102. The front tray 108 isillustrated in ghost such that the connection between the front tray 108and the base frame 102 is more easily viewed. In such embodiments, thefront tray 108 has a receiver slot 126 formed within the lateral sidewall. In the present embodiment, the receiver slot 126 may extendsubstantially vertically through the lateral side wall and then veerfrom the vertical orientation to a substantially horizontal orientation.The base frame 102 may define a pin 104 insertable into the receiverslot 126 of the front tray 108. Accordingly, when front tray 108 ispositioned on the base frame 102, the pin 104 may traverse thesubstantially vertical portion of the slot 126 and the tray may be pushforward in the +Y direction, as indicated in the depicted coordinateaxes, such that the pin 104 sits within the substantially horizontalportion, when the front tray 108 is positioned in the readyconfiguration. This may prevent unwanted movement of the front tray 108in the vertical direction once the pin 104 is within the substantiallyhorizontal portion of the receiver slot 126. In some embodiments, toprevent the front tray 108 from rotating about an axis defined by thepin 104, the front tray 108 may include a bottom securing strip 130 witha second slot 132 formed therein. The second slot 132 may include awidened portion and a narrow portion wherein a second pin 133 extendingfrom the base frame 102 can be inserted in to the wider portion, butwhen the front tray 108 is pushed forward to the ready configuration,the narrower portion locks in around the neck of the second pin 133,such that the front tray 108 cannot be lifted in the vertical direction.It is noted that while the slot and pin connections between the fronttray 108 and the base frame 102 are illustrated on one side of the fronttray 108, similar or identical slot and pin connections may be presenton the opposite side of the front tray 108.

Referring again to FIGS. 2A and 2B, the rear tray 110 is configured tobe positioned at a distal end (i.e., rearward) of the blade assembly 130and is configured to receive a portion of a tissue sample as the tissuesample is conveyed through the blade assembly 130 by the sample conveyor120. Stated another way, as a tissue sample 10 is passed through theblade assembly 130, a first portion of the tissue sample 10 is directedbetween the shoe 134 and the gripping roller 140 and a remainder portionof the tissue sample is directed over the blade clamp 136 toward therear tray 110 (see also FIG. 11B). The rear tray 110 accordinglysupports the remainder portion of the tissue sample that passes over theblade clamp 136 on a tissue support surface 111. Surrounding a portionof the tissue support surface 111 may be lip 125 extending from thetissue support surface 111, which is configured to retain the tissuesample 10 thereon. Accordingly, the portion of the tissue sample that isdirected onto the rear tray 110 can be retained on the rear tray 110instead of potentially falling off an end of the tissue support surface111. In some embodiments, the rear tray 110 may be electro-polished orprovided with a similar high durability and mirrored surface treatmentsuch that the rear tray 110 may be easily cleaned and sterilized.Alternatively, or in addition to such treatment, the rear tray 110 maybe made from a material capable of repeated washing and sterilization(e.g., stainless steel). Moreover, the rear tray 110 may be lightweightfor a user to easily manipulate, for example the rear tray 110 may weighless than 10 lbs.

FIG. 6A illustrates a perspective view of the rear tray 110 mounted onto the base frame 102. As noted herein, the rear tray 110 may be one ofthe disassemblable components of the plurality of disassemblablecomponents. In particular, FIG. 6A illustrates a connection between therear tray 110 and the base frame 102. In this case, the rear tray 110includes side walls 127 that have a slot 128 formed therein. A rear traypin 129 projecting from the base frame 102 is insertable into the slot128 to properly mount the rear tray 110 on to the base frame 102. Thebase frame 102 may also include locking pin 131 coupled to a handle 139that can extend through an aperture 113 formed within the side wall 127of the rear tray 110 to lock the rear tray 110 into place, in the readyconfiguration. The handle 139 may allow easy inserting and/or removingof the locking pin 131 to and from engagement with the rear tray 110. Insome embodiments, the locking pin 131 may be spring loaded and biased tothe locked position.

Referring now to FIG. 6B, the rear tray 110 is illustrated with analternative orientation as compared to FIG. 6A. As illustrated, in someembodiments, the rear tray 110 may be angled (i.e., oriented at anon-zero angle) relative to the front tray 108. Stated another way, thetissue support surface 111 may be angled relative to the sample supportsurface 121 of the front tray 108. In particular, the tissue supportsurface 111 may be angled downward in the −Y/−Z quadrant as indicativeby the illustrated coordinate axes. By angling the tissue supportsurface 111 of the rear tray 110 downward, gravity may aid in propellinga tissue sample through the blade assembly 130. In yet furtherembodiments, the rear tray 110 may be rotatably adjusted about an axisdefined by a connection between the base frame 102 and the rear tray 110to achieve various degrees of the rotation. Accordingly, the tissuesupport surface 111 of the rear tray 110 may be rotatably adjustablewith respect to the sample support surface 121 of the front tray 108 tovarious angles.

Referring again to FIG. 2B, the tissue planing assembly 100 furtherincludes the catch tray 112, which is configured to be positionedbeneath the blade assembly 130 and configured to catch a portion of thetissue sample as it is processed by the blade assembly 130. The catchtray 112 may be removably positioned beneath the blade assembly 130.Accordingly, the catch tray 112 may be included as one of disassemblablecomponents of the plurality disassemblable components. FIG. 7illustrates a perspective view of the catch tray 112 mounted onto thebase frame 102 beneath the blade assembly 130 so as to be able to catchthe portion of a tissue sample that is guided between the shoe 134 andthe gripping roller 140 (see FIG. 11B). The catch tray may include aperiphery lip 119 extending vertically on all sides of the catch tray toretain the portion of the tissue sample thereon and any fluids that flowdown to the catch tray that are used during processing. In theillustrated embodiments, the base frame 102 may define guide rails 114that the catch tray 112 may longitudinally traverse so as to be guidedinto position beneath the blade assembly 130. At least one of the guiderails 114 may include a stop 115 at an end of the guide rails 114configured to indicate that the catch tray 112 has reached thelongitudinal end of the guide rails. In some embodiments, the catch tray112 may be electro-polished or provided with a similar high durabilityand mirrored surface treatment such that the catch tray 112 may beeasily cleaned and sterilized. Alternatively, or in addition to suchtreatment, the catch tray 112 may be made from a material capable ofrepeated washing and sterilization (e.g., stainless steel).

Referring again to FIGS. 2A and 2B, rotatably mounted to the base frame102 may be a hold down roller 172. Referring to FIG. 8, a perspectiveview of the hold down roller 172 removably coupled to the base frame 102is depicted. The hold down roller 172 may include a roller frame 173 anda roller 174 rotably coupled to the frame. The hold down roller 172 as aunit may rotate toward the sample conveyor 120 to hold a tissue samplein contact with the sample conveyor 120 while still allowing the sampleto move through the cutting assembly. The hold down roller 172 may beremovably coupled to the base frame 102 using, for example, spring pins196 to lock the roller frame 173 of the hold down roller 172 to the baseframe 102. In some embodiments, the hold down roller 172 may be one ofthe disassemblable components of the plurality of disassemblablecomponents. The hold down roller may be made from any materials capableof repeated cleaning and sterilization.

Referring again to FIGS. 2A and 2B, as noted hereinabove, the tissueplaning assembly 100 may include a control unit 150. The control unit150 may be communicatively coupled to the sample conveyor 120 and canexecute logic to selectively operate the sample conveyor 120 so as toconvey a tissue sample toward the blade assembly 130 to perform a tissueplaning operation. The control unit 150 may be housed within the controlunit housing 151 that is connected to the base frame 102 by an arm 153,which may be adjustable (e.g., a stainless steel swivel arm).

FIG. 9 depicts a schematic diagram illustrating communication betweenthe control unit 150 and the sample conveyor 120, the status indicator155, the user input module 158 and the one or more component sensors170. The control unit 150 can be any type of computing device andincludes one or more processors 152 and one or more memory modules 154.The one or more processors 152 may include any device capable ofexecuting machine-readable instructions stored on a non-transitorycomputer-readable medium, such as those stored on the one or more memorymodules 154. Accordingly, each of the one or more processors 152 mayinclude a controller, an integrated circuit, a microchip, a computer,and/or any other computing device.

The one or more memory modules 154 are communicatively coupled to theone or more processors 152. The one or more memory modules 154 may beconfigured as volatile and/or nonvolatile memory and, as such, mayinclude random access memory (including SRAM, DRAM, and/or other typesof RAM), flash memory, secure digital (SD) memory, registers, compactdiscs (CD), digital versatile discs (DVD), and/or other types ofnon-transitory computer-readable mediums. Depending on the particularembodiment, these non-transitory computer-readable mediums may residewithin the electronic control unit 150, as shown, and/or external to theelectronic control unit 150. The one or more memory modules 154 may beconfigured to store logic (i.e., machine readable instructions) that,when executed by the one or more processors 152, cause the control unit150 to selectively control operation of the sample conveyor 120.

As noted above, the control unit 150 is communicatively coupled to thevarious electrical components of the tissue planing assembly 100 over acommunication path 156. The communication path 156 may be formed fromany medium that is capable of transmitting a signal such as, forexample, conductive wires, conductive traces, optical waveguides, or thelike. Moreover, the communication path 156 may be formed from acombination of mediums capable of transmitting signals. In someembodiments, the communication path 156 includes a combination ofconductive traces, conductive wires, connectors, and buses thatcooperate to permit the transmission of electrical data signals betweenthe various components of the components such as processors, memories,sensors, input devices, output devices, and communication devices.Additionally, it is noted that the term “signal” means a waveform (e.g.,electrical, optical, magnetic, mechanical or electromagnetic), such asDC, AC, sinusoidal-wave, triangular-wave, square-wave, vibration, andthe like, capable of traveling through a medium.

As noted above, the control unit 150 is communicatively coupled to thesample conveyor 120. For example, the control unit 150 may becommunicatively coupled to a motor of the sample conveyor 120 which isconfigured to rotatively drive the gripping roller 140 described above.The one or more processors 152 of the control unit 150 can execute logicstored on the one or more memory modules 154 to cause the control unit150 to operate or prevent operation of the sample conveyor 120.Conditions of operation will be discussed more fully below.

As noted above, the tissue planing assembly 100 may include one or morecomponent sensors 170 communicatively coupled to the control unit 150over the communication path 156. In embodiments, the one or morecomponent sensors 170 are configured to output a signal indicative of atleast one of the plurality of disassemblable components missing from theready configuration. That is when one or more of the disassemblablecomponents are not appropriately mounted on to the base frame 102 of thetissue planing assembly 100, the one or more component sensors 170output a signal indicating that at least one of the disassemblablecomponents is missing or is not properly mounted on to the base frame102. For example, the one or more component sensors 170 may includemagnetic sensors (e.g., magnet in-position switches). The one or morecomponent sensors 170 may be positioned on the base frame 102 so as todetect the presence and/or absence of the plurality of disassemblablecomponents, as generally indicated in FIG. 2A. Each of the one or moredisassemblable components may include one or more dedicated componentsensors 170 for detecting the individual disassemblable component. Asnoted herein, when the signal indicating that at least one of thedisassemblable components of the plurality of disassemblable componentsare missing from the ready configuration, the one or more processors 152can execute logic to prohibit operation of the sample conveyor 120 andprevent a tissue planing operation from being performed. Accordingly,the tissue planing assembly 100 may only be operational when completelyassembled in the ready configuration.

Communicatively coupled to the control unit 150 over the communicationpath 156 is a user input module 158. The user input module 158 mayinclude tactile input hardware (e.g., knob, lever, button, etc.) thatallows an operator to input commands into the control unit 150 tooperate the sample conveyor 120 to perform a tissue planing operation ona tissue sample 10. Referring to FIGS. 2A and 2B that user input module158 may be mounted onto the control unit housing 151 at a position awayfrom the blade assembly 130. The user input module 158 may include afirst hand control 157 and a second hand control 159 coupled to thecontrol unit housing 151. In such embodiments, the first hand control157 and the second hand control 159 are communicatively coupled to thecontrol unit 150 such that when the first hand control 157 and thesecond hand control 159 are activated, the one or more processors 152 ofthe control unit 150 (illustrated in FIG. 9) execute logic stored on theone or more memory modules 154 to activate the sample conveyor 120. Thefirst hand control 157 and the second hand control 159 may be biased toan unactivated position, such that continuous and concurrentmanipulation of the first and second hand controls 157, 159 to anactivated position is needed throughout processing. Accordingly, anoperator's hands must remain engaged with the first and second handcontrols 157, 159 throughout a tissue planing operation. Stated anotherway, if at least one of the first hand control 157 and the second handcontrol 159 is in a deactivated position, the control unit 150 may causethe sample conveyor 120 to stop its conveying movement.

Referring again to FIG. 9, in some embodiments, the tissue planingassembly 100 includes a status indicator 155 communicatively coupled tothe control unit 150 that is configured to indicate an operating statusof the tissue planing assembly 100. For example, and as shown in FIG.2A, the status indicator 155 may include a light mounted on the controlunit housing 151. The light may change color based on the operatingstatus of the tissue planing assembly 100. For example, when it isdetermined by the control unit 150 that one or more of thedisassemblable components are missing from the ready configuration basedon the signal from the one or more component sensors 170, the controlunit 150 may cause the light to glow red to indicate that the tissueplaning assembly 100 is not ready to perform a tissue planing operation(i.e., a not ready signal). If however, it is determined by the controlunit 150 that the plurality of disassemblable components are mounted inthe ready configuration, based on the signal from the one or morecomponent sensors 170, the control unit 150 may cause the light to glowblue to indicate that the tissue planing assembly 100 is ready toperform a tissue planing operation (i.e., a ready signal). When thefirst hand control 157 and the second hand control 159 are activated andthe tissue planing assembly 100 is ready to perform a tissue planingoperation, the control unit 150 may cause the light to glow green toindicate that the tissue planing assembly 100 is performing a tissueplanning operation (i.e., a running signal).

Referring again to FIG. 9, in some embodiments, the tissue planingassembly 100 may include an emergency stop 180 communicatively coupledto the control unit 150 that, when activated outputs a signal thatcauses the control unit 150 to immediately stop the tissue planingoperation. In some embodiments the emergency stop 180 includes tactileinput hardware such as a button that can quickly and easily be depressedby a user. Referring to FIG. 2A, the emergency stop 180 may be mountedto the housing 151 of the control unit 150 in proximity to the userinput module 158.

FIG. 10 illustrates a flow diagram 200 representing an exemplary methodof processing a tissue sample with the tissue planing assembly 100 asdescribed herein. Though the various steps of the method are illustratedas having a discrete number in a particular order, a greater or fewernumber of steps in various orders may be used without departing from thescope of the present disclosure. With concurrent reference to FIG. 11A,to process a tissue sample 10 with the tissue planing assembly 100, thetissue sample 10 having a epidermis layer 12 and a dermis layer 14 isplaced epidermis side down on the front tray 108 of the tissue planingassembly 100 (step 202). In some embodiments, the front tray 108 and/orthe tissue sample 10 may be wetted with saline to reduce the coefficientof friction between the surface of the front tray 108 and the tissuesample 10. Accordingly, potential unwanted stretching from sticking tothe front tray 108 and resultant rebound of the tissue sample 10 afterplaning may be reduced.

During step 202, a portion of the tissue sample 10 may be contacted tothe sample conveyer such that during operation the sample conveyor 120will be able to convey the tissue sample 10 without further adjustmentof the tissue sample 10 on to the sample conveyor 120. In embodimentsincluding a hold down bar, the hold down bar can be rotated so as toapply a downward pressure to a leading edge of the tissue sample 10 tofacilitate initiation of the tissue planing operation and to maintainconsistent and constant pressure on the tissue sample 10 as it isprocessed.

It is noted that in some embodiments, the tissue sample 10 may includean adipose layer 16, such as shown in FIG. 1, that is larger than orequal to 25.4 mm. Through experimentation, it was found that adiposelayers of larger than or equal to 25.4 mm may aid in maintaining theintegrity of the tissue sample 10 throughout processing. That isinstances of tearing of the tissue sample 10 were reduced as compared totissue samples having thinner adipose layers. For tissue samples with anadipose layer 16 of less than 25.4 mm, a surrogate adipose layer may bepositioned on top of the tissue sample 10 in between the tissue sample10 and the hold down roller 172. For example a sheet of semi rigidpolystyrene foam having a thickness of about 25.4 mm (1 inch) may beused as a surrogate adipose layer. In some embodiments, a plastic meshmay be placed on top of the adipose layer 16 between the tissue sample10 and the hold down roller 172 to further aid in transportation of thetissue sample 10 over the blade assembly 130.

Referring again to FIG. 10, at step 204 the control unit 150 may, basedon the signal of the one or more component sensors 170, determinewhether one or more disassemblable components of the tissue planingassembly 100 are assembled to the base frame 102 of the tissue planingassembly 100 in a ready configuration. If it is determined that one ofthe one or more disassemblable components is missing or is not properlyassembled to the base frame 102, as shown in FIGS. 2A and 2B, at step206 the control unit 150 may output a not ready signal with the statusindicator 155, described above, indicating that the one or moredisassemblable components of the tissue planing assembly 100 are notassembled to the base frame 102 of the tissue planing assembly 100 inthe ready configuration. Once properly assembled, as determined by thecontrol unit 150 based on the signal of the one or more componentsensors 170, at step 208 the control unit 150 can output a ready signalwith the status indictor as described above indicating that the one ormore disassemblable components are assembled to the base frame 102 ofthe tissue planing assembly 100 in the ready configuration and that thetissue planing assembly 100 is, accordingly, ready to perform a tissueplaning operation. With the tissue planing assembly 100 properlyassembled, at step 210 an operator may concurrently and/or continuouslyengage the first hand control 157 and the second hand control 159 tocause the control unit 150 to operate the sample conveyor 120 to conveythe tissue sample 10 through the blade assembly 130 of the tissueplaning assembly 100.

Referring to FIG. 11B, as the tissue sample 10 is introduced to theblade assembly 130 a portion of the tissue sample 10 comprising theepidermis and a portion of the dermis is directed downward between theshoe 134 and the gripping roll to be caught in the catch pan. Thisportion may be thin enough (e.g., less than or equal to about 0.65 mm)to use as a skin graft, for example, for burn victims or the like. Asecond portion of the tissue sample 10 is directed above the bladeassembly 130 to the rear tray 110. This portion may include the dermisand any adipose tissue that was connected to the dermis. In someembodiments, the remainder dermis and adipose layer may be re-runthrough the blade assembly to retrieve a dermis only product. Suchdermis product may have a thickness of about 1.0 mm to about 5 mm.

Between uses or between processing tissue from different donors, thetissue planing assembly 100 may be disassembled, cleaned, sterilized,and reassembled for future use. Set up and breakdown may take about 15minutes or less for each operation.

It should now be understood that embodiments described herein aredirected to tissue planing assemblies and methods. In particular, tissueplaning assemblies as described herein are capable processing tissuesamples epidermis side down resulting in larger skin graft products.Moreover, embodiments described herein include easily disassemblablecomponents which allow for easy disassembly, sterilization, andreassembly. Embodiments described herein also include prevention ofoperation when the tissue planing is not properly assembled or operatedwhich may improve yield and reduce incidents related to improperassembly.

It is noted that the terms “substantially” and “about” may be utilizedherein to represent the inherent degree of uncertainty that may beattributed to any quantitative comparison, value, measurement, or otherrepresentation. These terms are also utilized herein to represent thedegree by which a quantitative representation may vary from a statedreference without resulting in a change in the basic function of thesubject matter at issue.

While particular embodiments have been illustrated and described herein,it should be understood that various other changes and modifications maybe made without departing from the spirit and scope of the claimedsubject matter. Moreover, although various aspects of the claimedsubject matter have been described herein, such aspects need not beutilized in combination. It is therefore intended that the appendedclaims cover all such changes and modifications that are within thescope of the claimed subject matter.

What is claimed is:
 1. A tissue planing assembly comprising: a baseframe; a plurality of disassemblable components assembled to the baseframe and having a ready configuration, wherein the plurality ofdisassemblable components is configured to support a tissue sample; asample conveyor; a blade assembly configured to be coupled to the baseframe, wherein the sample conveyor is configured to convey the tissuesample through the blade assembly; a control unit communicativelycoupled to the sample conveyor; and one or more component sensorscommunicatively coupled to the control unit, the one or more componentsensors configured to output a signal indicative of at least one of theplurality of disassemblable components missing from the readyconfiguration, wherein the control unit prohibits operation of thesample conveyor when at least one of the plurality of disassemblablecomponents is missing from the ready configuration.
 2. The tissueplaning assembly of claim 1, wherein the plurality of disassemblablecomponents comprises a front tray, wherein the sample conveyor isconfigured to pull the tissue sample from the front tray and through theblade assembly.
 3. The tissue planing assembly of claim 2, wherein thefront tray comprises a receiver slot configured to receive a pin of thebase frame.
 4. The tissue planing assembly of claim 1, wherein theplurality of disassemblable components comprises a rear tray configuredto be positioned at a distal end of the blade assembly and configured toreceive a portion of the tissue sample as the tissue sample is conveyedthrough the blade assembly by the sample conveyor.
 5. The tissue planingassembly of claim 4, wherein the rear tray is oriented such that atissue support surface of the rear tray is set at an angle with respectto a front tray.
 6. The tissue planing assembly of claim 5, wherein therear tray is rotatably adjustable about an axis to adjust the angle ofthe rear tray.
 7. The tissue planing assembly of claim 4, wherein therear tray is lockable in the ready configuration.
 8. The tissue planingassembly of claim 1, wherein the plurality of disassemblable componentscomprises a catch tray configured to be positioned beneath the bladeassembly and configured to catch a portion of the tissue sample as it isprocessed by the blade assembly.
 9. The tissue planing assembly of claim1, further comprising a rotatable hold down bar coupled to the baseframe and configured to hold down the tissue sample as the sampleconveyor conveys the tissue sample through the blade assembly.
 10. Thetissue planing assembly of claim 1, further comprising a statusindicator communicatively coupled to the control unit, wherein thestatus indicator is configured to produce a signal indicative of anoperating status of the tissue planing assembly, wherein the operatingstatus includes a ready signal, wherein each of the plurality ofdisassemblable components are positioned within the ready configuration,a not ready signal, wherein at least one of the plurality ofdisassemblable components is not positioned within the readyconfiguration, and a running signal, wherein the tissue planing assemblyis operating.
 11. A tissue planing assembly comprising: a base frame; asample conveyor coupled to the base frame; a blade assembly coupled tothe base frame, wherein the sample conveyor is configured to convey atissue sample through the blade assembly; a control unit communicativelycoupled to the sample conveyor; and a first hand control and a secondhand control communicatively coupled to the control unit, wherein thecontrol unit executes logic to operate the sample conveyor only whenboth the first hand control and the second hand control are activated.12. The tissue planing assembly of claim 11, further comprising acontrol unit housing, wherein the control unit housing is pivotallycoupled to the base frame.
 13. The tissue planing assembly of claim 12,wherein the first hand control and the second hand control are coupledto the control unit housing.
 14. The tissue planing assembly of claim11, further comprising a catch tray removably positioned beneath theblade assembly and configured to catch a portion of the tissue sample asit is processed by the blade assembly.
 15. The tissue planing assemblyof claim 14, further comprising one or more component sensorscommunicatively coupled to the control unit, the one or more componentsensors configured to output a signal indicative of the catch traymissing from a ready configuration, wherein the tissue planing assemblyis only operable when the catch tray is positioned within the readyconfiguration.
 16. The tissue planing assembly of claim 11, furthercomprising: one or more trays removably couplable to the base frame; andone or more component sensors communicatively coupled to the controlunit, the one or more component sensors configured to output a signalindicative of one or more of the one or more trays missing from a readyconfiguration, wherein the tissue planing assembly is only operable wheneach of the one or more trays are positioned within the readyconfiguration.
 17. A tissue planing assembly comprising: a base frame; asample conveyor coupled to the base frame; and a blade assembly coupledto the base frame, wherein the sample conveyor is configured to convey atissue sample through the blade assembly, the blade assembly comprising:a shoe defining a groove; a blade positioned on a top surface of theshoe proximate to the groove; a blade clamp configured to rigidly clampthe blade to the shoe; and one or more spacers positionable within thegroove adjacent to the blade to adjust a cutting depth of the blade. 18.The tissue planing assembly of claim 17, wherein the sample conveyorcomprises a gripping roller positioned relative to a cutting edge of theblade, wherein a position of the cutting edge of the blade is adjustablerelative to the gripping roller.
 19. This tissue planing assembly ofclaim 17, wherein the one or more spacers are positionable within thegroove behind the blade in a longitudinal direction.
 20. The tissueplaning assembly of claim 17, wherein each of the one or more spacerscorrespond to a resulting skin graft thickness.